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M. Age‐related changes in the brain of the dog. Vet Pathol 1999; 36(3): 202–211.

      13 13 Simmons MM. Lafora disease in the cow? J Comp Pathol 1994; 110(4): 389–401.

      14 14 Saunders LZ. Cerebrovascular siderosis in horses. AMA Arch Pathol 1953; 56: 637–642.

      15 15 Hurst EW. Calcification in the brain of equidae and bovidae. Am J Pathol 1934; 10: 795–798.

      16 16 Furuoka H, Yamada M, Miyazawa K, Taniyama H and Matsui T. Dense microspheres in normal horse brain. Acta Neuropathol (Berl) 1996; 91(4): 440–443.

      17 17 Wells GA and Wells M. Neuropil vacuolation in brain: a reproducible histological processing artefact. J Comp Pathol 1989; 101(4): 355–362.

      18 18 Wheeler SJ. Quantitative and qualitative morphology of equine peripheral nerve: teased fibre studies. Res Vet Sci 1990; 48(2): 145–151.

      19 19 Wheeler SJ and Plummer JM. Age‐related changes in the fibre composition of equine peripheral nerve. J Neurol Sci 1989; 90(1): 53–66.

      20 20 Sippel WL. Pacinian corpuscles in peripheral nerves. Cornell Vet 1942; 32: 314–316.

      21 21 Asbury AK. Renaut bodies. A forgotten endoneurial structure. J Neuropathol Exp Neurol 1973; 32(2): 334–343.

      22 22 Ortman JA, Sahenk Z and Mendell JR. The experimental production of Renaut bodies. J Neurol Sci 1983; 62(1–3): 233–241.

      23 23 Aleman M, Lecouteur RA, Nieto JE, et al. Sarcoplasmic masses in equine skeletal muscle. Neuromuscul Disord 2005; 15(2): 147–153.

      24 24 Waller A. Experiments on the section of the glossopharyngeal and hypoglossal nerves of the frog, and observations of the alterations produced thereby in the structure of their primitive fibres. Phil Transact Royal Soc London 1850; 140: 423–429.

      25 25 Stoll G and Muller HW. Nerve injury, axonal degeneration and neural regeneration: basic insights. Brain Pathol 1999; 9(2): 313–325.

      26 26 Stoll G, Jander S and Myers RR. Degeneration and regeneration of the peripheral nervous system: from Augustus Waller's observations to neuroinflammation. J Peripher Nerv Syst 2002; 7(1): 13–27.

      27 27 Huxtable C, Summers BA and de Lahunta A. Atlas of Veterinary Neuropathology. Cornell University, College of Veterinary Medicine, Ithaca, NY. 2002. Available from: https://secure.vet.cornell.edu/oed/Neuropathology/index.asp. Accessed 2022_01_28.

      28 28 Anderson P. Pathology Education Informational Resource (PEIR), Digital Library in University of Alabama at Birmingham Available from: https://peir.path.uab.edu/library/index.php?/category/19. Accessed 2022_02_28

      29 29 Science T. M. I. o. M. (2011). Essential Brain Anatomy & Neuropathology (EBA&N). Retrieved from The Neuropathology Database of the Tokyo Metropolitan Institute of Medical Science, https://pathologycenter.jp/english/en_index.html. Accessed 2022_02_28.

      30 30 Kortz GD, Madigan JE, Lakritz J and Goetzman BW. Cerebral oedema and cerebellar herniation in four equine neonates. Equine Vet J 1992; 24(1): 63–66.

      31 31 Miranda IC, Taylor KR, Castleman W, et al. Schwannosis in three foals and a calf. Vet Pathol 2019; 56(5): 783–788.

      32 32 Taylor KR, MacKay RJ, Nelson EA, et al. Spinal cord hamartomatous myelodysplasia in 2 horses with clinical neurologic deficits. Vet Pathol 2016; 53(4): 844–846.

      33 33 Middleton JR, Valdez R, Britt LG, Parish SM and Tyler JW. Progressive hindlimb paraparesis in a goat associated with a vascular hamartoma. Vet Rec 1999; 144(10): 264–265.

5 Disorders of behavior

      The location of lesions resulting in disorders of behavior essentially involves the forebrain, and such lesions can be focal, multifocal, and diffuse. Because normal behavior is extremely variable among species, breeds, individuals, and especially stages of reproductive cycles, if after a neurologic examination the only finding is a history of or evidence of a subtle change in expected behavior, the examiner must be cautious while assuming that a morbid lesion in the forebrain accounts for the signs.

      Frantic behavior of a bull during the mating season, jerky collapsing in a white pig with sunburn in full sun, bizarre antics of a mare in diestrus, and violent kicking in a colt having a new bandage applied over the hock all attest to unusual behavior syndromes that can easily be mistaken for morbid brain disorders.

Subtle alterations in behavior resulting from organic brain disorders include the following: continual yawning—that can be prominent in hepatoencephalopathy; a tendency to drift to one side when walking—that is often present with asymmetric lesions; and a lack of recognition of familiar animals (Figure 5.1), people, and objects—that is often the earliest expression of cerebral disease in foals. More prominent signs are seizures (Chapter 6), compulsive walking and circling (Figure 5.2), pressing the head on objects, running around frantically, biting at animate (including self) (Figure 5.3) and inanimate (Figure 5.4) objects, leaving food in the mouth, and adopting bizarre postures of the head, neck, trunk and limbs. Such syndromes are usually referable to lesions in the frontal lobes, temporal lobes, internal capsule, limbic system, thalamus or basal nuclei, or due to diffuse brain disease.

Figure 5.1 A newborn Thoroughbred foal that is not distracted by the presence of people, does not attend to the dam, and postures with its head flagging alongside its flank is behaving very abnormally and is likely suffering from forebrain disease. With such a syndrome, this foal did have an undiagnosed, aseptic meningoencephalitis from which it survived.

Figure 5.2 A patient that is variably obtunded and spontaneously turns and walks toward one side will have an asymmetric lesion in the forebrain, usually worse on the side toward which it turns—right in this case. This lamb has a chronic suppurative and granulomatous ependymitis and ventriculitis on the right side. Additional signs of forebrain involvement were poor vision and poor menace response in the left eye (with normal pupils) and decreased sensation perceived from the left nasal septum compared with the right. Typical of many lesions associated with perilesional edema, and especially those involving forebrain, the signs would wax and wane in severity so that at times the lamb would walk, trot, and run quite well in both directions. The only consistent abnormality with gait and posture was a delay in protracting the left limbs, especially the left forelimb as shown here, while turning right and while attempting to hop on each left limb in turn. This likely represents abnormal conscious proprioceptive processing from the left side of the body and limbs.

      Usually, localized and diffuse lesions affecting only the forebrain result in combinations of behavioral

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